A machine learning model to estimate myocardial stiffness from EDPVR

Babaei, Hamed; Mendiola, Emilio A.; Neelakantan, Sunder; Xiang, Qian; Vang, Alexander; Dixon, Richard A. F.; Shah, Dipan J.; Vanderslice, Peter; Choudhary, Gaurav; Avazmohammadi, Reza

doi:10.1038/s41598-022-09128-6

Cited by 24 publications

(8 citation statements)

References 55 publications

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“…21 Also, the proposed phantom can be used to generate synthetic data to develop machine-learning surrogates for image registration such that kinematic biomarkers can be quantified through only basic measurements from raw DICOM/Nifty images. 22,23 The use of deep learning to perform image registration in the lungs from raw images has gained increasing popularity in recent times. 5,24 While machine learning models can be trained using publicly available repositories, one limitation is the lack of availability of four-dimensional CT (4DCT) image stacks in human patients.…”

Section: Discussionmentioning

confidence: 99%

In-silico CT lung phantom generated from finite-element mesh

Neelakantan,

Mukherjee,

Smith

et al. 2024

Medical Imaging 2024: Image-Guided Procedures, Robotic Interventions, and Modeling

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Several lung diseases lead to alterations in regional lung mechanics, including ventilator-and radiation-induced lung injuries. Such alterations can lead to localized underventilation of the affected a r eas, r e sulting i n the overdistension of the surrounding healthy regions. Thus, there has been growing interest in quantifying the dynamics of the lung parenchyma using regional biomechanical markers. Image registration through dynamic imaging has emerged as a powerful tool to assess lung parenchyma's kinematic and deformation behaviors during respiration. However, the difficulty in validating the image registration estimation of lung de formation, primarily due to the lack of ground-truth deformation data, has limited its use in clinical settings. To address this barrier, we developed a method to convert a finite-element ( FE) mesh of t he l ung i nto a p hantom computed tomography (CT) image, advantageously possessing ground-truth information included in the FE model. The phantom CT images generated from the FE mesh replicated the geometry of the lung and large airways that were included in the FE model. Using spatial frequency response, we investigated the effect o f " i maging p a rameters" such as voxel size (resolution) and proximity threshold values on image quality. A series of high-quality phantom images generated from the FE model simulating the respiratory cycle will allow for the validation and evaluation of image registration-based estimations of lung deformation. In addition, the present method could be used to generate synthetic data needed to train machine-learning models to estimate kinematic biomarkers from medical images that could serve as important diagnostic tools to assess heterogeneous lung injuries.

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Section: Discussionmentioning

confidence: 99%

In-silico CT lung phantom generated from finite-element mesh

Neelakantan,

Mukherjee,

Smith

et al. 2024

Medical Imaging 2024: Image-Guided Procedures, Robotic Interventions, and Modeling

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“…Through the SRR framework presented in this study, significant improvements in image quality, and strain calculations were achieved. This rigorous quantification of 4D strains can further be used in conjunction with real-time volumetric, and hemodynamic readings to estimate the intrinsic material properties of the myocardium [ 54 ]. Thus, a multiscale mathematical approach comprising organ-level measurements, and tissue-level mechanical characteristics can be posed to assist in clinical intervention.…”

Section: Discussionmentioning

confidence: 99%

Complete spatiotemporal quantification of cardiac motion in mice through enhanced acquisition and super-resolution reconstruction

Mukherjee,

Keshavarzian,

Fugate

et al. 2024

Preprint

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The quantification of cardiac motion using cardiac magnetic resonance imaging (CMR) has shown promise as an early-stage marker for cardiovascular diseases. Despite the growing popularity of CMR-based myocardial strain calculations, measures of complete spatiotemporal strains (i.e., three-dimensional strains over the cardiac cycle) remain elusive. Complete spatiotemporal strain calculations are primarily hampered by poor spatial resolution, with the rapid motion of the cardiac wall also challenging the reproducibility of such strains. We hypothesize that a super-resolution reconstruction (SRR) framework that leverages combined image acquisitions at multiple orientations will enhance the reproducibility of complete spatiotemporal strain estimation. Two sets of CMR acquisitions were obtained for five wild-type mice, combining short-axis scans with radial and orthogonal long-axis scans. Super-resolution reconstruction, integrated with tissue classification, was performed to generate full four-dimensional (4D) images. The resulting enhanced and full 4D images enabled complete quantification of the motion in terms of 4D myocardial strains. Additionally, the effects of SRR in improving accurate strain measurements were evaluated using an in-silico heart phantom. The SRR framework revealed near isotropic spatial resolution, high structural similarity, and minimal loss of contrast, which led to overall improvements in strain accuracy. In essence, a comprehensive methodology was generated to quantify complete and reproducible myocardial deformation, aiding in the much-needed standardization of complete spatiotemporal strain calculations.

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“…Indeed, transmural variations from a counter-clockwise twist at the sub-endocardial layers to clockwise epicardial twisting, predicted by T 3D , are expected in light of myocardial helicity ranging from positive to negative angles from the endocardial layers to the epicardium. 4,[18][19][20] In contrast, minimal changes in T 3D peaks were observed transmurally between subendocardial layers to the epicardium along all the slices post-MVR (Fig. 1b).…”

Section: Advantages Of T 3d In Characterizing Torsionmentioning

confidence: 99%

Four-dimensional assessment of left ventricular torsion in mitral valve prolapse using CMR

Mukherjee,

Mendiola,

Neelakantan

et al. 2024

Medical Imaging 2024: Image Processing

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The heterogeneity in myofiber helicity across the cardiac wall causes twisting (torsion) in the left ventricle (LV) during contraction, which is a significant contributor to its pumping function. Although important progress has been made in identifying and studying a quantitative "global" metric for torsion, four-dimensional (4D) torsion characteristics in the LV remain underexplored. We propose an imaging-based framework that uses myocardial motion obtained from cine cardiac magnetic resonance (CMR) scans of the LV to calculate torsion. We performed our LV torsion analysis in a mitral valve prolapse (MVP) human patient (n=1) pre-and post-MV repair. Establishing a high-fidelity torsion measure in the LV offers a rigorous regional marker to investigate the potential reversal of cardiac remodeling post-surgical interventions, such as MV repair. After image acquisition, a non-rigid image registration algorithm was used to calculate 4D LV displacements. Twisting was evaluated through (i) an in-plane rotation-based approximation (referred to as T 2D ) and (ii) a three-dimensional formulation involving in-plane and through-plane strains (referred to as T 3D ). Comparing T 2D to T 3D , broad regions of positive (counter-clockwise) rotation, captured through T 3D , were unrepresented by T 2D despite a qualitative agreement between the two metrics in capturing the average regional torsion. Also, the presence of comprehensive transmural positive torsion at the apical section was opposed to negative epicardial torsion at the midsection. Such variations in torsional behavior, captured by T 3D , are expected due to transmural helicity in fiber orientation. Overall, the underlying effects of through-plane shear in characterizing LV torsion were evidenced, and the image registration framework offered a comprehensive tool to capture 4D myocardial torsion that can complement conventional LV global markers.

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A machine learning model to estimate myocardial stiffness from EDPVR

Cited by 24 publications

References 55 publications

In-silico CT lung phantom generated from finite-element mesh

In-silico CT lung phantom generated from finite-element mesh

Complete spatiotemporal quantification of cardiac motion in mice through enhanced acquisition and super-resolution reconstruction

Four-dimensional assessment of left ventricular torsion in mitral valve prolapse using CMR

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